A software product including codes for the method of determining parasitic resistance and capacitance from a layout of an lsi is executed by a computer. The method is achieved by providing a plurality of patterns of a wiring structure which contains a target interconnection; and by producing a library configured to store parameters indicating the parasitic resistance and the parasitic capacitance in relation to the target interconnection to each of the plurality of patterns. The producing is achieved by calculating the parameters to a plurality of conditions corresponding to deviation in manufacture of the wiring structure for each of the plurality of patterns.
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1. A computer-readable software product comprising codes, executed by a computer, for a method of determining parasitic resistance and capacitance from a layout of an lsi, said method comprising:
providing a plurality of patterns of a wiring structure which contains a target interconnection; and
producing a library configured to store parameters indicating said parasitic resistance and said parasitic capacitance of said target interconnection for each of said plurality of patterns,
wherein said producing comprises:
calculating said parameters for a plurality of conditions corresponding to deviation in manufacture of said wiring structure for each of said plurality of patterns,
wherein said plurality of conditions comprises a 0th condition to a second condition,
a desired width and desired film thickness of said target interconnection are w0 and T0, respectively, standard deviations of a distribution of said width of said target interconnection and a distribution of said film thickness thereof are σw and σT, respectively, and said width w and said film thickness T in actual manufacture of said target interconnection are expressed, by using coefficients αw and αT, as
W=W0+αw*σw and T=T0+αT*σT, said 0th condition is a case where said width w and said film thickness T are w0 and T0, respectively,
said first condition is a case where a delay in said target interconnection is maximized under a condition that αw2+αT2 is constant, and
said second condition is when the delay in said target interconnection is minimized under the condition that αw2+αT2 is constant.
14. A computer-readable software product comprising codes, executed by a computer, for a method of determining parasitic resistance and capacitance from a layout of an lsi, by referring a library, wherein a wiring structure which contains a target interconnection is a pattern, and said library stores parameters indicating said parasitic resistance and said parasitic capacitance of said target interconnection for a plurality of conditions for variation in manufacture of said wiring structure with respect to each of a plurality of said patterns, said method comprising:
reading a netlist of said lsi;
reading a layout data indicating said layout of said lsi;
calculating said parasitic resistance and said parasitic capacitance in each of said plurality of conditions for each of said interconnections contained in said layout by referring to said parameters stored in said library; and
generating a netlist with parasitic rc by adding the calculated parasitic resistance and the calculated parasitic capacitance to said netlist,
wherein a desired width and desired film thickness of said target interconnection are w0 and T0, respectively, standard deviations of a distribution of said width of said target interconnection and a distribution of said film thickness thereof are σw and σT, respectively, and said width w and said film thickness T in actual manufacture of said target interconnection are expressed, by using coefficients αw and αT, as
W=W0+αw*σw and T=T0+αT*σT, said plurality of conditions comprises a 0th condition to a second condition,
said 0th condition is a case where said width w and said film thickness T are w0 and T0, respectively,
said first condition is a case where a delay in said target interconnection is maximized under a condition that αw2+αT2 is constant, and
said second condition is when the delay in said target interconnection is minimized under the condition that αw2+αT2 is constant.
2. The software product according to
in case of said second condition, said one is minimized and the other is maximized.
3. The software product according to
a deviation of another factor which relates to said delay is ranged from +σ0 to −σ0,
said first condition is the case where said delay is maximized under the condition that the deviation of said another factor is one of +σ0 and −σ0 and αw2+αT2 is constant,
said third condition is the case where said delay is maximized under the condition that the deviation of said another factor is the other of +σ0 and −σ0 and αw2+αT2 is constant,
said second condition is the case where said delay is minimized under the condition that the deviation of said another factor is one of +σ0 and −σ0 and αw2+αT2 is constant, and
said fourth condition is the case where said delay is minimized under the condition that the deviation of said another factor is the other of +σ0 and −σ0 and αw2+αT2 is constant.
4. The software product according to
said coefficients αw and αT in said second condition are equal to said coefficients αw and αT in said fourth condition.
5. The software product according to
a ratio βR of said parasitic resistance to said center resistance and a ratio βC of said parasitic capacitance to said center capacitance value are stored as said parameter to each of said first to fourth conditions.
6. The software product according to
reading a netlist of said lsi;
reading a layout data indicating said layout of said lsi;
calculating said parasitic resistance and said parasitic capacitance in each of said plurality of conditions to each of said interconnections contained in said layout by referring to said center resistance value, said center capacitance value, and the ratios βR and βC stored in said library; and
generating a netlist with parasitic rc by adding the calculated parasitic resistance and the calculated parasitic capacitance to said netlist.
7. The software product according to
calculating said parasitic resistance and said parasitic capacitance in each of said first to fourth conditions by multiplying the ratios βR and βC by said center resistance value and said center capacitance value, respectively.
8. The software product according to
generating correction ratios βR′ and βC′ by correcting said ratios βR and βC based on a configuration of a node; and
calculating said parasitic resistance and said parasitic capacitance in each of said first to fourth conditions by multiplying the correction ratios βR′ and βC′ by said center resistance value and said center capacitance value, respectively.
9. The software product according to
a summation of lengths of the interconnections in said group is Li (i is an integer equal to or more than 1 and equal to or smaller than N),
said ratio βC and said correction ratio βC′ are the following equation:
βC′=1+(βC−1)γC a parameter γC satisfies the following equation:
10. The software product according to
said ratio βR and said correction ratio βR′ are the following equation:
βR′=1+(βR−1)γR said parameter γR satisfies the following equation:
11. The software product according to
a sub interconnection group in n interconnection layer (n is an integer equal to or more than 1 and equal to or smaller than N) is connected in series to one interconnection in said interconnection group,
a summation of lengths of the interconnections in said sub interconnection group is Lj (j is an integer equal to or more than 1 and equal to or smaller than n),
said ratio βR and said correction ratio βR′ to said one interconnection are the following equation:
βR′=1+(βR−1)γR said parameter γR satisfies the following equation:
12. The software product according to
13. The software product according to
15. The software product according to
a deviation of another factor which relates to said delay is ranged from +σ0 to −σ0,
said first condition is the case where said delay is maximized under the condition that the deviation of said another factor is one of +σ0 and −σ0 and αw2+αT2 is constant,
said third condition is the case where said delay is maximized under the condition that the deviation of said another factor is the other of +σ0 and −σ0 and αw2+αT2 is constant,
said second condition is the case where said delay is minimized under the condition that the deviation of said another factor is one of +σ0 and −σ0 and αw2+αT2 is constant, and
said fourth condition is the case where said delay is minimized under the condition that the deviation of said another factor is the other of +σ0 and −σ0 and αw2+αT2 is constant.
16. The software product according to
a ratio βR of said parasitic resistance to said center resistance and a ratio βC of said parasitic capacitance to said center capacitance value are stored as said parameter to each of said first to fourth conditions.
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This application is a division of application Ser. No. 11/341,581, filed Jan. 30, 2006, now pending, and based on Japanese Patent Application No. 2005-024557, filed Jan. 31, 2005, by Kenta Yamada, the disclosures of which are incorporated herein by reference in their entirety. This application claims only subject matter disclosed in the parent application and therefore presents no new matter.
1. Field of the Invention
The present invention relates to a technique to design a semiconductor device, and in particular, relates to a technique to perform an LPE (Layout Parameter Extraction) process for a layout of a semiconductor device.
2. Description of the Related Art
In designing a semiconductor device by using a computer (CAD system), layout design is carried out based on a netlist (information showing connection relationship between logic elements) after logic design is carried out. After a layout is determined, various types of verification processes are conducted to check whether the layout satisfies a design rule, or whether a device having the layout properly operates, and so on. An LPE (Layout Parameter Extraction) process is known as one process carried out in the verification process.
In the LPE process, extraction of a parasitic resistance and a parasitic capacitance (referred to as “parasitic RC” hereinafter) relevant to an interconnection in the obtained layout is carried out. Such a parasitic RC is a parameter that can be determined only after the layout is determined, and is not included in the netlist. Therefore, an extracted parasitic RC is added to the netlist, and the netlist containing the parasitic RC (referred to as “netlist with parasitic RC” hereinafter) is generated. That is to say, a tool for carrying out the LPE process inputs a netlist and a layout data, and outputs a netlist with parasitic RC.
After that, a delay verifying process and a timing verifying process are carried out for a device on the design by using the obtained netlist with parasitic RC. When the result of the verifying process indicates a “fail” state, the above layout design process is carried out again. Then, the LPE process and the verifying process are again carried out. The above processes are repeated until the layout “passes” the verifying process. If the result of the verifying process indicates a “passed” state, a final layout data is determined.
Japanese Laid Open Patent Application (JP-P2001-265826A) discloses a technique related to the LPE process. In a circuit simulation device disclosed in Japanese Laid Open Patent Application (JP-P2001-265826A), layout information of an integrated circuit is stored in a first storage section. Also, interconnection variations information is stored in a second storage section. Process information showing a manufacturing process of an integrated circuit is stored in a third storage section. An interconnection resistance and capacitance extracting section extracts interconnection resistance and capacitance in which variation are taken into consideration based on the layout information, the interconnection variations information, and the process information, and generates a netlist that includes the extracted interconnection resistance and interconnection capacitance. A simulation section inputs the generated netlist, and conducts a delay analysis of the integrated circuit in consideration of the interconnection variations.
As stated above, the LPE process is an important process requiring high accuracy to determine whether or not a designed semiconductor device properly operates. Here, in an actual manufacturing process of a semiconductor device, a structure of an interconnection and so on may not be manufactured as precisely as is intended. In other words, an interconnection layer width, an interconnection layer thickness, an interlayer insulating film thickness, and so on may possibly indicate variations from desired values. Such a variation is referred to as a “process variation” hereinafter. The process variation affect a delay in a circuit. Since the process variation may be caused, it is possible that an actual product does not operate properly, even if a designed layout passes an operation verifying process of the computer.
In the LPE process, therefore, it is desirable to extract the parasitic RC in consideration of the process variation. It is also desirable to conduct a verifying process for a plurality of netlists with parasitic RC in which the process variation is taken into consideration. Consequently, a layout data is produced that can cope with some extent of the process variation. If a product is manufactured based on the layout data, a probability that the product is defective is reduced even if the process variation is generated.
However, when the process variation is considered, time for carrying out the LPE process and the delay verifying process is greatly increased, as compared with a case where the process variation is not considered. As stated above, the process variation include variations of a plurality of parameters such as the interconnection layer width and the interlayer insulating film thickness, and the number of combinations of the variations is huge. It is virtually impossible to extract the parasitic RC and carry out the delay verifying process for all the combinations. The above conventional example (Japanese Laid Open Patent Application (JP-P2001-265826A)) gives suggestion of the LPE process and the verifying process taking the process variation into consideration. However, the conventional example does not describe a specific method of reducing the time for the LPE process and the verifying process. A technique is demanded that can reduce the time for semiconductor device design while considering the process variation.
An aspect of the present invention relates to a computer-readable software product including codes, executed by a computer, for a method of determining parasitic resistance and capacitance from a layout of an LSI. In this case, the method is achieved by providing a plurality of patterns of a wiring structure which contains a target interconnection; and by producing a library configured to store parameters indicating the parasitic resistance and the parasitic capacitance in relation to the target interconnection to each of the plurality of patterns. The producing is achieved by calculating the parameters to a plurality of conditions corresponding to deviation in manufacture of the wiring structure for each of the plurality of patterns.
Here, the plurality of conditions includes a 0th condition to a second condition, and a desired width and desired film thickness of the target interconnection are W0 and T0, respectively, standard deviations of a distribution of the width of the target interconnection and a distribution of the film thickness thereof are σW and σT, respectively, and the width W and the film thickness T in actual manufacture of the target interconnection are expressed, by using coefficients σW and σT, as
W=W0+αW*σW
and
T=T0+αT*σT.
In this case, the 0th condition is a case where the width W and the film thickness T are W0 and T0, respectively, the first condition is a case where a delay in the target interconnection is maximized under a condition that αW2+αT2 is constant, and the second condition is when the delay in the target interconnection is minimized under the condition that αW2+αT2 is constant.
Also, in case of the first condition, one of the parasitic resistance of and the parasitic capacitance related to the target interconnection is maximized, and the other is minimized, and in case of the second condition, the one is minimized and the other is maximized.
Also, the plurality of conditions further contains a third condition and a fourth condition, and a deviation of another factor which relates to the delay is ranged from +σ0 to −σ0. The first condition is the case where the delay is maximized under the condition that the deviation of the another factor is one of +σ0 and −σ0 and αW2+αT2 is constant, and the third condition is the case where the delay is maximized under the condition that the deviation of the another factor is the other of +σ0 and −σ0 and αW2+αT2 is constant. The second condition is the case where the delay is minimized under the condition that the deviation of the another factor is one of +σ0 and −σ0 and αW2+αT2 is constant, and the fourth condition is the case where the delay is minimized under the condition that the deviation of the another factor is the other of +σ0 and −σ0 and αW2+αT2 is constant.
Also, the coefficients αW and αT in the first condition are equal to the coefficients αW and αT in the third condition, and the coefficients αW and αT in the second condition are equal to the coefficients αW and αT in the fourth condition.
In this case, a center resistance value as a value of the parasitic resistance and a center capacitance value as a value of the parasitic capacitance are stored in a library as the parameter to the 0th condition. A ratio βR of the parasitic resistance to the center resistance and a ratio βC of the parasitic capacitance to the center capacitance value are stored in the library as the parameter to each of the first to fourth conditions.
Also, the method may be achieved by further reading a netlist of the LSI; reading a layout data indicating the layout of the LSI; calculating the parasitic resistance and the parasitic capacitance in each of the plurality of conditions to each of the interconnections contained in the layout by referring to the parameters stored in the library; and generating a netlist with parasitic RC by adding the calculated parasitic resistance and the calculated parasitic capacitance to the netlist.
Also, the method may be achieved by further reading a netlist of the LSI; reading a layout data indicating the layout of the LSI; calculating the parasitic resistance and the parasitic capacitance in each of the plurality of conditions to each of the interconnections contained in the layout by referring to the center resistance value, the center capacitance value, and the ratios βR and βC stored in the library; and generating a netlist with parasitic RC by adding the calculated parasitic resistance and the calculated parasitic capacitance to the netlist.
In this case, the calculating may be achieved by calculating the parasitic resistance and the parasitic capacitance in each of the first to fourth conditions by multiplying the ratios βR and βC by the center resistance value and the center capacitance value, respectively.
Also, the calculating may be achieved by generating correction ratios βR′ and βC′ by correcting the ratios βR and βC based on a configuration of a node; and calculating the parasitic resistance and the parasitic capacitance in each of the first to fourth conditions by multiplying the correction ratios βR′ and βC′ by the center resistance value and the center capacitance value, respectively.
In this case, when the node comprises a group of interconnections in each of N interconnection layers (N is a natural number), a summation of lengths of the interconnections in the group is Li (i is an integer equal to or more than 1 and equal to or smaller than N), and the ratio βC and the correction ratio βC′ are the following equation:
βC′=1+(βC−1)γC
a parameter γC satisfies the following equation:
Also, when the interconnection groups are connected in series in the node, and the ratio βR and the correction ratio βR′ are the following equation:
βR′=1+(βR−1)γR
the parameter γR satisfies the following equation:
Also, when the interconnection groups is branched in the node, a sub interconnection group in n interconnection layer (n is an integer equal to or more than 1 and equal to or smaller than N) is connected in series to one interconnection in the interconnection group, a summation of lengths of the interconnections in the sub interconnection group is Lj (j is an integer equal to or more than 1 and equal to or smaller than n), the ratio βR and the correction ratio βR′ to the one interconnection are the following equation:
γR′=1+(βR−1)γR
the parameter γR satisfies the following equation:
In this case, when a plurality of the correction ratios βR′ are calculated to the one interconnection, the largest one of the plurality of correction ratios βR′ is adopted.
Also, the largest one of a plurality of the correction ratios βC′ is adopted as a coupling capacitance between the nodes.
Another aspect of the present invention relates to a computer-readable software product includes codes, executed by a computer, for a method of determining parasitic resistance and capacitance from a layout of an LSI, by referring a library, wherein a wiring structure which contains a target interconnection is a pattern, and the library stores parameters indicating the parasitic resistance and the parasitic capacitance in relation to the target interconnection to a plurality of conditions for variation in manufacture of the wiring structure with respect to each of a plurality of the patterns. The method is achieved by reading a netlist of the LSI; by reading a layout data indicating the layout of the LSI; by calculating the parasitic resistance and the parasitic capacitance in each of the plurality of conditions to each of the interconnections contained in the layout by referring to the parameters stored in the library; and by generating a netlist with parasitic RC by adding the calculated parasitic resistance and the calculated parasitic capacitance to the netlist.
Here, a desired width and desired film thickness of the target interconnection are W0 and T0, respectively, standard deviations of a distribution of the width of the target interconnection and a distribution of the film thickness thereof are σW and σT, respectively, and the width W and the film thickness T in actual manufacture of the target interconnection are expressed, by using coefficients αW and αT, as
W=W0+αW*σW
and
T=T0+αT*σT.
The plurality of conditions comprises a 0th condition to a second condition, and the 0th condition is a case where the width W and the film thickness T are W0 and T0, respectively. The first condition is a case where a delay in the target interconnection is maximized under a condition that αW2+αT2 is constant, and the second condition is when the delay in the target interconnection is minimized under the condition that αW2+αT2 is constant.
Also, the plurality of conditions further contains a third condition and a fourth condition, and a deviation of another factor which relates to the delay is ranged from +σ0 to −σ0. The first condition is the case where the delay is maximized under the condition that the deviation of the another factor is one of +σ0 and −σ0 and αW2+αT2 is constant, and the third condition is the case where the delay is maximized under the condition that the deviation of the another factor is the other of +σ0 and −σ0 and αW2+αT2 is constant. The second condition is the case where the delay is minimized under the condition that the deviation of the another factor is one of +σ0 and −σ0 and αW2+αT2 is constant, and the fourth condition is the case where the delay is minimized under the condition that the deviation of the another factor is the other of +σ0 and −σ0 and αW2+αT2 is constant.
Also, a center resistance value as a value of the parasitic resistance and a center capacitance value as a value of the parasitic capacitance are stored in a library as the parameter to the 0th condition, and a ratio βR of the parasitic resistance to the center resistance and a ratio βC of the parasitic capacitance to the center capacitance value are stored in the library as the parameter to each of the first to fourth conditions.
In still another aspect of the present invention, a method of manufacturing a semiconductor device which has a plurality of wiring layers, is achieved by determining design criteria, and a manufacturing condition of the semiconductor device; by carrying out layout design of the semiconductor device based on functional specification and the design criteria to produce a layout data; by estimating process variations of width and thickness of each of interconnections for every wiring layer from the layout data based on the design criteria and the manufacturing condition; by determining an interconnection delay affected by a specific condition of the process variations for every wiring layer; by repeating correction of the layout data, the estimation and the determination until the determined interconnection delay meets the function specification, to produce a final layout data; and by manufacturing the semiconductor device based on the final layout data and the manufacture condition. The determining an interconnection delay is achieved by determining a variation of the interconnection delay by using of parasitic resistance and parasitic capacitance for every wiring layer through statistical relaxation in which the process variations of width and thickness of each of interconnections are independent between the plurality of wiring layers.
Hereinafter, a semiconductor device design system of the present invention with reference to the attached drawings.
The storage unit 10 is realized by a hard disk unit, for example, and configured to store an RC library 11, a netlist 12, a layout data 13, a netlist with parasitic RC 14, and an interconnection length data 15. As described later in detail, the RC library 11 is referred to at the time of a LPE process, showing a parameter (referred to as an “RC parameter” hereinafter) relevant to a parasitic capacitance and a parasitic resistance of an interconnection (referred to as a “parasitic RC” hereinafter). The netlist 12 is a data showing connection relationship between logic elements in a semiconductor device (LSI) under design. The layout data 13 shows a layout of the LSI under design. The layout data 13 is generated by an automatic layout tool (not shown), and is stored in the storage unit 10. The netlist with parasitic RC 14 is a netlist having a parasitic RC obtained by LPE process to be mentioned later. The interconnection length data 15 shows a length of each interconnection in the layout.
The processing unit 20 can access the storage unit 10. The LPE tool 30 is a computer program (software product) executed by the processing unit 20. The LPE tool 30 is provided with a library building section 31 having a function of building up the RC library 11, and an RC extracting section 32 having a function of carrying out the LPE process. The verifying tool 40 is a computer program executed by the processing unit 20, having a function of carrying out an operation verifying process (delay verifying process and timing verifying process) of the designed LSI.
As the input unit 50, a key board and a mouse are exemplified. A user (designer) can input various data and commands by using the input unit 50, while viewing information displayed on the display unit 60. By using the semiconductor device design system 1 described above, the LPE process and the operation verifying process are carried out.
The processing unit 20 carries out a process shown below in accordance with commands of the LPE tool 30 and the verifying tool 40.
Step S10:
First of all, the RC library 11 is built up by the library building section 31 in the LPE tool 30. The RC library 11 stores an RC parameter showing the parasitic RC of an interconnection (wiring) from which the RC parameter should be extracted (referred to as “target interconnection” hereinafter). As the RC parameter, a value of the parasitic RC itself may be stored, or a ratio of the parasitic RC to a predetermined reference value may be stored. The RC parameter is calculated for each of various interconnection layers, various shape (width and thickness) of the target interconnection, and various types of interconnection environment around the target interconnection. Such shape and peripheral interconnection environment are referred to as a “pattern (interconnection structure or wiring structure)” hereinafter.
The library building section 31 automatically generates various possible patterns, and calculates (simulates) the parasitic RC for each of the various patterns. The calculated parasitic RC (RC parameter) is stored in the RC library 11 in the storage unit 10. That is, the RC library 11 shows the RC parameters for the various patterns. Here, according to the present invention, the RC library 11 shows a plurality of RC parameter under “a plurality of conditions” for a single pattern. The plurality of conditions correspond to various types of variation at the manufacturing (process variation). The plurality of conditions will be described later in detail. Additionally, the RC library 11 just needs to be carried out only once in advance for one technology (process). The same RC library 11 is used for all the products that are based on the same technology.
Step S20:
A layout of an LSI that corresponds to the netlist 12 is determined by an automatic layout tool and manual operation not shown. The layout data 13 showing the determined layout is stored in the storage unit 10.
Step S30:
Next, the LPE process (parasitic RC extracting process) is carried out by the RC extracting section 32 in the LPE tool 30. First, the RC extracting section 32 (the processing unit 20) reads the netlist 12 and the layout data 13 stored in the storage unit 10.
Step S40:
Secondly, the RC extracting section 32 extracts (calculates) the parasitic RC for every interconnection contained in a layout shown by the layout data 13.
Step S50:
The RC extracting section 32 generates the netlist with parasitic RC 14, by adding the parasitic RC calculated at the step S40, to the netlist 12.
Step S60:
Next, the operation verifying process (the delay verifying process and the timing verifying process) of the designed LSI are carried out by the verifying tool 40. The verifying tool 40 (the processing unit 20) reads the netlist with parasitic RC generated at the step S50 from the storage unit 10, and carries out the operation verifying process based on the read-out netlist with parasitic RC 14. When the result of the operation verifying process indicates a “fail” state (step S70: No), the step S20 is again carried out. That is, correction of the layout is carried out based on the verifying process result, and the layout data 13 is again generated. After that, the LPE process and the operation verifying process are again carried out. When the result of the operation verifying process indicates a “passed” state (step S70: Yes), the layout data 13 generated at the step S20 is adopted as a final layout data.
As would be clarified later, the present invention makes it possible to reduce a process time at the step S40. Also, the number of times to return from the step 70 to the step 20 is reduced. As a result, the design time of the semiconductor device is greatly reduced. Detailed description of the present invention is given below, based on the above overview.
1. Process Variation
First, “process variation” relevant to the present invention will be described in detail. In an actual manufacturing process of a semiconductor device, a structure of an interconnection and so on, may not be manufactured as precisely as is intended. In other words, a cross-sectional area (width and thickness) of the interconnection, a thickness of an interlayer insulating film, and so on may give variation from a desired value. Such a process variation affect the parasitic RC of the interconnection, further affecting a delay.
As shown in
W=WO+αW∘σW
T=TO+αT∘σT (1)
Each of the coefficients αW and αT can take a value in a range of −A to +A. The value A is 3, for example. At this time, the width W is expressed in a range of ±3σW (a range of 99.7%) from a central value W0, which is statistically enough. The same is applied to the film thickness T. A case where the coefficient αW is ±A corresponds to a case where the width W varies to a maximum extent. Also, a case where the coefficient αT is ±A corresponds to a case where the film thickness T varies to a maximum extent.
According to the present invention, correlation mentioned below is considered for the width W and the film thickness T.
Correlation 1:
A correlation does not exist between the width W variation and the film thickness T variation with respect to a certain interconnection. In other words, an event “width W variation” and an event “film thickness T variation” are independent of each other. That is to say, the coefficients αW and αT are variables independent of each other. This could be understood from the fact that a process of determining the thickness of an interconnection layer and a process of determining the width of the interconnection are separate in a general manufacturing process of the semiconductor device. For example, as shown in
Correlation 2:
A correlation exists between the width W variation of the interconnection with respect to the same interconnection layer. This could be understood from the fact that an interconnection is formed by using a mask and etching in the general manufacturing process of the semiconductor device. For example, when the width W of the target interconnection 70 is larger than the center condition W0 in the interconnection layer M1, the width of the interconnection 71a is also increased as shown in
Correlation 3:
A correlation does not exist between the width W variations of the interconnection with respect to a different interconnection layers. Also, a correlation does not exist between the film thickness T variations of the interconnection with respect to the different interconnection layers. This could be understood from the fact that the different interconnection layers are formed in different processes in the general manufacturing process of the semiconductor device. For example, the width W of the target interconnection 70 formed in the interconnection layer M1 is larger than the center condition W0, while the width of the interconnection 71b formed in the interconnection layer M2 is smaller than the center condition, as shown in
2. Building-Up of the RC Library
Next, the building-up of the RC library 11 according to the present invention, namely, the step S10 in
A case where the coefficient αW is ±3 corresponds to a case where the width W varies to a maximum extent. Also, a case where the coefficient αT is ±3 corresponds to a case where the film thickness T varies to a maximum extent. It should be noted here as stated above, that the correlation does not exist between the width W variation and the film thickness T variation, and that the coefficients αW and αT are the variables independent of each other (the correlation 1). This means that a probability P that both of the width W and the film thickness T vary to a maximum extent at the same time (αW=±3, αT=±3) is extremely small. For examples, variation shown by the point Q (+3σW, +3σT) in
√{square root over (αW2+αT2)}=3 (2)
In other words, the restriction that a sum of squares of ratios of the process variations (αW, αT) to the standard deviations is constant, is imposed to the width W and the film thickness T. Under this restriction, it is sufficient that the corner conditions in which the delay of the target interconnection 70 is maximized and minimized is calculated. That is, the point P on a circle CIRC in
As shown in
According to the present invention as described above, the “statistical relaxation” is taken into consideration, and the corner conditions are calculated in which the delay time is maximized and minimized. In other words, the conditions that take process variation into consideration include two corner conditions (first and second conditions) at least. Although only the width W and the film thickness T of the interconnection are taken into consideration in the above description, other factors relevant to the delay time may be considered as well. Examples of the other factors are such as the thickness of the interlayer insulting film, the dielectric constant of the interlayer insulating film, and a via-contact resistance. At this time, each of the other factors is set to vary to a maximum extent (±3σ).
Under the second condition, the width W, the film thickness T, the thickness of the interlayer insulating film, the dielectric constant, and the via-contact resistance are given as αW2*σW, αT2*σT, −3σ, +3σ, and +3σ, respectively. The coefficients αW2 and αT2 correspond to the point P2, for example, and correspond to the case where the parasitic capacitance is minimized and the parasitic resistance is maximized (Cmin and Rmax). Under a fourth condition, the width W, the film thickness T, the thickness of the interlayer insulating film, the dielectric constant, and the via resistance are given as αW4*σW, αT4*σT, +3σ, −3σ, and −3σ, respectively. The coefficients αW4 and αT4 correspond to the point P2, and correspond to the case where the parasitic capacitance is minimized and the parasitic resistance is maximized (Cmin′ and Rmax′). That is, the coefficients αW2 and αW4 are equal, and the coefficients αT2 and αT4 are equal. However, variation of the other factors are different between the second and fourth conditions. The variation of the other factors are set to one of +3σ or −3σ in the second condition, while the variation of the other factors are set to the other in the fourth condition. Therefore, calculated parasitic RC are different between the second and fourth conditions.
In this way, the four corner conditions of the present invention are determined. It is sufficient that the parasitic RC is calculated through simulation for each of the five conditions of the center condition (the zero condition) and the four corner conditions (the first to fourth conditions). Consequently, the RC library 11 of the present invention is built up.
Next, an RC parameter showing the calculated parasitic RC is stored in the RC library 11 (step S15). With respect to the center condition, for example, the calculated parasitic RC is stored as the RC parameter with no change. On the other hand, with respect to the four corner conditions, the ratio (corner ratios βR and βC) to the parasitic RC under the center condition is stored as the RC parameter. As a result, a calculation time in the LPE process is reduced as described later. When a calculation process is not completed for all the patters (step S16: No), the above steps S13 to S15 are repeated for patterns where calculation is not yet completed. If the calculation process is completed for all the patterns (step S16: Yes), the RC library 11 of the present invention is completed (step S17).
In this way, according to the RC library 11 of the present invention, the process variation is taken into consideration, but is narrowed down to the four corner conditions. Therefore, a memory capacity can be saved. Also, the time for the LPE process is reduced by using the RC library 11 built in the above way, as described below. Additionally, the RC library 11 just needs to be carried out only once beforehand, for one technology (minimum size). The same RC library 11 is used for all the products that are based on the same technology.
3. LPE Process (RC Extracting Process)
Next, the LPE process of the present invention, namely, the step 40 in
First, one target interconnection 70 is selected from a plurality of interconnections included in a layout of an LSI under design (step S41). Subsequently, the RC library 11 shown in
Next, a parasitic RC of the target interconnection 70 under the corner conditions is extracted. More specifically, the corner ratios βR and βC (RC parameters) are read for each of the plurality of patterns that are referred to at the step S42 (step S43). For example, corner ratios βC1-1 to βC1-4, and βR1-1 to βR1-4 in the pattern 1 are read out. Then, it is selected whether or not a correction process is carried out for the read-out corner ratios (step S44). In the first embodiment of the present invention, the correction process is not carried out, and the read-out corner ratios βR and βC are used for the next calculation with no change (step S44: No). More specifically, a resistance value R (Corner) under a certain corner condition is calculated by multiplying the center resistance value R (Center) obtained at the step S42 and a certain corner ratio βR together. Also, a capacitance value C (Corner) under a certain corner condition is calculated by multiplying the center capacitance value C (Center) obtained at the step S42 and a certain corner ratio βC (step S45).
R(corner)=βR∘R(center)
C(corner)=βC∘C(center) (3)
For example, a case is discussed here, where the parasitic RC under the first condition relevant to the target interconnection 70 shown in
It has already been carried out at the step S42, which of the plurality of patterns stored in the RC library 11 is adaptable for an interconnection. At the step S45, therefore, it is not necessary to carry out a matching process of interconnection and any of the plurality of patterns stored in the RC library 11. Additionally, it is possible to calculate the parasitic RC under the four corner conditions with the easy calculation shown by the equations (3), since the RC parameter relevant to the four corner conditions is stored in the form of the corner ratios βR and βC. Therefore, the load on a computer is reduced, and a calculation speed is improved.
When the RC extracting process is not yet completed for all the interconnections included in the layout (step S46: No), another interconnection is set as the target interconnection 70, and the steps S42 to S45 are repeated. If the RC extracting process is completed for all the interconnections included in the layout (step S46: Yes), the LPE process is finished.
As described above, according to the present invention, various conditions showing the process variation are narrowed down to the above first to fourth conditions. At the step S50 shown in
Further, according to the present invention, the “statistical relaxation” is taken into consideration when the RC parameter under the first to fourth conditions is calculated. That is, a case that a probability is statistically very low is excluded from the process variation. Since it is not necessary to support unnecessary cases, a fail rate in the delay verifying process can be reduced. Because of the reduction in the fail rate of the delay verifying process, the number of times to correct the layout and again carry out the delay verifying process is greatly reduced. In other words, the number of times to repeat the layout process and the verifying process is greatly reduced, since it is not necessary to generate the layout data 13 that supports extreme cases. Therefore, the TAT can be reduced, and the design time of the semiconductor device is reduced.
According to the second embodiment of the present invention, a correction process to be mentioned later is carried out to the corner ratios βR and βC read out at the above step S43 shown in
R(corner)=βR′∘R(center)
C(corner)=βC′∘C(center) (4)
In the second embodiment, the correction ratios βR′ and βC′ are given by the following equations (5) by use of predetermined correction parameters γR and γC.
βR′=1+(βR−1)∘γR
βC′=1+(βC−1)∘γC (5)
The correction parameters γR and γC are determined based on the idea of the “statistical relaxation”, as shown below.
As stated above, in case of different interconnection layers, there is no correlation between variations of the widths W of the interconnections, and between variations of the film thicknesses T of the interconnections (correlation 3). That is, “independence” exists between interconnection layers. Therefore, a probability that a delay is maximized and minimized in all the interconnection layers at the same time, is considered to be extremely small. In other words, it is overly negative to consider that the corner conditions are satisfied in all the interconnection layers at the same time. In
Here, calculation of a parasitic capacitance will be discussed. In each interconnection layer, a parasitic capacitance per unit length is assumed to be given as a common value C0. Also, in each interconnection layer, a corner ratio βC is assumed to be given as a common value β. Although such assumption is not always satisfied in reality, an error derived from this assumption is considered not to be large. What affects the change in delay is a long interconnection. However, various patterns exist in the long interconnection and the changes in delay are averaged. Therefore, the above assumption is likely to be satisfied in case of the long interconnection. Under the assumption, a total of parasitic capacitance Ctot under the center condition is given as Ctot=C0*(L1+L2+L3). On the other hand, the total of parasitic capacitance Ctot under the corner conditions is given as Ctot=β*C0*(L1+L2+L3). A change in capacitance that results from the interconnection layers M1 to M3 is given as ΔC1=C0*(β−1)*L1, ΔC2=C0*(β−1)*L2, and ΔC3=C0*(β−1)*L3, respectively. Since the independence exists between the respective interconnection layers, a total of the changes is statistically given as the following:
(ΔC12+ΔC22+ΔC32)1/2/(ΔC1+ΔC2+ΔC3)=C0*(β−1)*γC
That is to say, in the example shown in
As seen from the equation (6), the correction parameters γR and γC are larger than 0 and smaller than 1. When all the interconnection lengths L1 to L3 are equal, the correction parameters γR and γC are 0.58. Therefore, as seen from the equation (5), the correction ratio βR′ is smaller than the corner ratio βR, and the correction ratio βC′ is smaller than the corner ratio βC. This means that the corner conditions are relaxed. That is, variation resulting from the center conditions to be considered, can be further reduced. The corner conditions originally obtained based on the statistical relaxation in the first embodiment, can be further reduced in the second embodiment. Since it is not necessary to support unnecessary cases, the fail rate in the delay verifying process is further reduced. Consequently, the number of times to repeat the layout process and verifying process can be further reduced.
More generally, it is assumed that the node 80 includes an interconnection group in each of N layers (N is a natural number) of interconnection layers. The interconnection group in a certain interconnection layer may include a plurality of interconnection elements. It is assumed that a sum of the lengths of interconnection elements in an interconnection group in each interconnection layer, is given as Li (i is an integer number equal to or larger than 1, and equal to or smaller than N). At this time, the correction parameters γR and γC are given as the following equation (7).
In this case, the correction parameter γC for the parasitic capacitance is given by the same equation as the above equation (6) or (7). However, the correction parameter γR for the parasitic resistance is different for each of the interconnection elements. More specifically, as for a line that includes the interconnection elements 85 and 86, the existence of the interconnection element 87 is ignored, and the correction parameter γR is given as γR(a) in the following equations (8). On the other hand, as for a line that includes the interconnection elements 85 and 87, the existence of the interconnection element 86 is ignored, and the correction parameter γR is given as γR(b) in the following equations (8).
As for the interconnection elements 85 located on the uppersteam side from the connecting point 84, two kinds of correction parameters γR(a) and γR(b) are calculated as candidates. In this case, the larger one of the two correction parameters is adopted as the correction parameter γR relevant to the interconnection element 85. Thus, when the connecting node is provided in the node 80, the correction parameter γR is calculated separately for each of the lines connected in series. For example, when all the interconnection lengths L1 to L3 are equal in the example shown in
More generally, it is assumed that the node 80 includes an interconnection group in each of N (N is a natural number) interconnection layers. In the node 80, a certain line is assumed to include a “sub interconnection group” connected in series in n (n is an integer number equal to or larger than 1, and equal to or smaller than N) interconnection layers. Also, it is assumed that a sum of the lengths of the interconnection elements in the interconnection group is given as Lj (j is an integer number equal to or larger than one, and equal to or smaller than n). At this time, the correction parameter γR for the line is given by the following equation (9).
By using the correction parameters γR and γC described above, the corner ratios βR and βC are corrected, and the correction ratios βR′ and βC′ are calculated (see the equation (5)). Then, by using the calculated correction ratios βR′ and βC′, the parasitic RC under the corner conditions is calculated (see
According to the second embodiment, the same effect as that of the first embodiment can be attained. Further, according to the second embodiment, the “statistical relaxation” is further carried out for a corner ratio β. As a result, the fail rate in the delay verifying process is further reduced. Consequently, the TAT can be further reduced, and the design time of the semiconductor device can be further reduced.
According to the design technique of the semiconductor device of the present invention, the number of a plurality of conditions showing process variation is limited. In particular, the conditions that show the process variation are narrowed down to the four conditions which are necessary and sufficient. As a result, a time for one LPE process is reduced. That is to say, reduction in the design time of the semiconductor device is realized.
Further, according to the design technique of the semiconductor device of the present invention, a case that has statistically very low probability among the process variation is excluded in carrying out the LPE process. That is, the “statistical relaxation” is applied to the LPE process. Since it is not necessary to support unnecessary cases, the fail rate in the delay verifying process is reduced. The number of times to correct a layout and again perform the delay verifying process is greatly reduced, since the fail rate in the delay verifying process is reduced. That is, the TAT can be reduced, and the reduction in the design time of the semiconductor device can be realized.
Further, according to the manufacturing method of the semiconductor device of the present invention, it is possible to prevent an over margin of the design, since the method of the statistical relaxation is used, and variation of an interconnection delay time is estimated through exclusion of conditions that seem rare as actual manufacturing conditions. It is also possible to expect a high manufacturing yield and provide a high-quality semiconductor device, since variation of manufacturing conditions that seem possible in reality are take into consideration.
That is to say, when layout design of a semiconductor device is carried out, a design rule and manufacturing conditions (requirement specifications for a manufacturing process for satisfying the design rule) of the semiconductor device are usually determined in advance. The design rule includes minimum patterns of an interconnection width, interconnection space, and so on. Thus, it is determined in advance, to which extent of variation interconnection width, capacitance film thickness, layer resistance value, and dielectric constant should be manufactured. In carrying out the layout design of the semiconductor device, an interconnection pattern is determined based on the design rule such that functional specifications of the semiconductor device to be designed are realized. Generally, if the layout design of the semiconductor device is seemingly completed, manufacturing variation of the semiconductor device is considered, and variation of actual interconnection delay is estimated from the layout pattern. Then, a simulation is carried out to see whether or not the predetermined functions are realized. According to the present invention, it is possible to conduct the simulation under the consideration of actual manufacturing variation. Then, the pattern is formed on a semiconductor substrate to manufacture the semiconductor device in accordance with the verified layout pattern, by use of known methods. Consequently, it is possible to prevent an over margin of the layout design, and realize a space-saving layout, since variation of manufacturing conditions rare in reality are excluded. At the same, it is possible to expect a high manufacturing yield, and provide a high-quality semiconductor device, since the layout pattern takes variation of manufacturing conditions possible in reality, into consideration.
According to a semiconductor device design technique of the present invention, the number of a plurality of conditions showing process variation is limited. In particular, conditions showing the process variation are narrowed down to four conditions which are necessary and sufficient. Consequently, the time taken for one LPE process is reduced. That is, reduction in a design time of the semiconductor device is realized.
Further, according to the semiconductor device design technique of the present invention, the LPE is carried out with exclusion of a case that is statistically very low in probability among the process variation. That is to say, “statistical relaxation” is applied to the LPE. Since it is not necessary to support unnecessary cases, a fail rate in the delay verifying process is reduced. Because of the reduction in the fail rate in the delay verifying process, the number of times to correct the layout and again perform the delay verifying process is greatly reduced. In other words, TAT (Turn Around Time) is reduced, realizing a reduction in the design time of the semiconductor device.
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